Glucose-Fueled Micromotors with Highly Efficient Visible-Light Photocatalytic Propulsion

Wang, Qinglong; Dong, Renfeng; Wang, Chun; Xu, Shuyu; Chen, Decheng; Liang, Yingjing; Ren, Biye; Gao, Wei; Cai, Yue‐Peng

doi:10.1021/acsami.8b17563

“…[13] Reported designs feature Janus micromotors based on photoactive materials,s uch as Cu 2 O/Au, bismuth oxyiodide,T iO 2 ,o rC 3 N 4 nanomaterials. [15] BiVO 4 -based micromotors can be readily activated by visible-light irradiation for enhanced capture of microorganisms. [15] BiVO 4 -based micromotors can be readily activated by visible-light irradiation for enhanced capture of microorganisms.…”

Section: Introductionmentioning

confidence: 99%

Visible‐Light‐Driven Janus Microvehicles in Biological Media

Pacheco

¹

,

Jurado‐Sánchez

²

,

Escarpa

³

2019

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Alight-driven multifunctional Janus micromotor for the removal of bacterial endotoxins and heavy metals is described. The micromotor was assembled by using the biocompatible polymer polycaprolactone for the encapsulation of CdTeo rC dSe@ZnS quantum dots (QDs) as photoactive materials and an asymmetric Fe 3 O 4 patch for propulsion. The micromotors can be activated with visible light (470-490 nm) to propel in peroxide or glucose media by adiffusiophoretic mechanism. Efficient propulsion was observed for the first time in complex samples such as human blood serum. These properties were exploited for efficient endotoxinremoval using lipopolysaccharides from Escherichia coli O111:B4 as am odel toxin. The micromotors were also used for mercury removal by cationic exchange with the CdSe@ZnS core-shell QDs.C ytotoxicity assays in HeLa cell lines demonstrated the high biocompatibility of the micromotors for future detoxification applications.Supportinginformation and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.

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Section: Motion Mechanismmentioning

confidence: 99%

“…With the illumination of blue‐violet light (λ ≈430−490 nm) through the microscope objective, the particles achieved self‐propulsion with a speed up to 15 μm s −1 . More importantly, a visible‐light (<700 nm) photocatalytic micromotor can be propelled at a speed of 18.71 μm s −1 with glucose as fuel. Such micromotor was composed of cuprous oxide (Cu 2 O) (photocatalytic active material) and 1.35% N‐doped carbon nanotubes (N‐CNTs) (improving catalytic activity).…”

Section: Motion Mechanismmentioning

confidence: 99%

Emerging Micro/Nanomotor‐Based Platforms for Biomedical Therapy

Wang

¹

,

Tu

²

,

Chen

³

et al. 2020

Advanced Intelligent Systems

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Highly efficient and versatile natural motors play a pivotal role in biological processes. Inspired by these biological motors, researchers developed their synthetic counterparts that can convert various energies into locomotion. With the potential to revolutionize the biomedical treatment process, these micro/ nanomotors have been attracting a booming research enthusiasm since the birth of the first micro/nanomotor 15 years ago (since 2004). First, typical motion mechanisms are elucidated and a detailed comparison is provided regarding their efficiency in a biological context. Next, cutting-edge proof-of-concept biomedical applications of the motors are overviewed, including on-demand drug dispensing, cell transporting, and precise microsurgery. Current achievements and remaining bottlenecks are discussed, to spur more collaboration among chemistry, nanoengineering, and the biomedical fields. With increasing attention and continuing innovation of the field, clinical translation of micro/nanomotors is possible in the next 15 years.

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“…According to previous reports, [20] the photoexcited electrons can be transferred also to the Fe 3 O 4 catalytic patch in the micromotors (via semiconductor junctions), [21] and recombine with its electronic levels,c reat- ing h + pairs.T he positive holes can react with water and asmall amount of peroxide or glucose present in the medium to initiate complex radical chain reactions and produce various products such as H + ,O 2 (for peroxide) or arabinose, erythrose,a nd formic acid (for glucose). [15] This leads to an accumulation of photodegradation products around the micromotor surface,w hich further propels the micromotors. Interestingly,a si llustrated in Figure 2B and Movie S2, micromotors can propel efficiently in tap water, human serum, and blood samples.T he time-lapse images demonstrate the effective displacement and prolonged micromotor propulsion over ap eriod of 50 su nder light irradiation, as compared with the negligible displacement in the absence of light.…”

Section: Synthesis Of the Visible-light-driven Qd/fe 3 O 4 Micromotormentioning

confidence: 99%

“…[14] Cu 2 O micromotors doped with carbon nanotubes can be efficiently driven by visible-light-triggered photocatalytic reactions of glucose. [15] BiVO 4 -based micromotors can be readily activated by visible-light irradiation for enhanced capture of microorganisms. [16] Yet, applications have been mostly directed to environmental remediation, and only near-infrared light has been exploited for triggered drug-release schemes.…”

Section: Introductionmentioning

confidence: 99%

Visible‐Light‐Driven Janus Microvehicles in Biological Media

Pacheco

¹

,

Jurado‐Sánchez

²

,

Escarpa

³

2019

View full text Add to dashboard Cite

Alight-driven multifunctional Janus micromotor for the removal of bacterial endotoxins and heavy metals is described. The micromotor was assembled by using the biocompatible polymer polycaprolactone for the encapsulation of CdTeo rC dSe@ZnS quantum dots (QDs) as photoactive materials and an asymmetric Fe 3 O 4 patch for propulsion. The micromotors can be activated with visible light (470-490 nm) to propel in peroxide or glucose media by adiffusiophoretic mechanism. Efficient propulsion was observed for the first time in complex samples such as human blood serum. These properties were exploited for efficient endotoxinremoval using lipopolysaccharides from Escherichia coli O111:B4 as am odel toxin. The micromotors were also used for mercury removal by cationic exchange with the CdSe@ZnS core-shell QDs.C ytotoxicity assays in HeLa cell lines demonstrated the high biocompatibility of the micromotors for future detoxification applications.Supportinginformation and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.

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Glucose-Fueled Micromotors with Highly Efficient Visible-Light Photocatalytic Propulsion

Cited by 84 publications

References 40 publications

Visible‐Light‐Driven Janus Microvehicles in Biological Media

Visible‐Light‐Driven Janus Microvehicles in Biological Media

Emerging Micro/Nanomotor‐Based Platforms for Biomedical Therapy

Visible‐Light‐Driven Janus Microvehicles in Biological Media

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